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Online since: August 2010
Authors: Shi Wei Zhang, Li Yuan Hou, Yong Chao Han, Yuan Hua Xie
Material Science and Engineering, B69-70 (2000), p. 500
[2] Wu.
J.of Membrane Science, 172 (2000), p. 199 [3] C.
Nanostructured Materials, 3 (1993), P. 19 [6] C.
Materials Science and Engineering, A220 (1996), P. 69 [8] Ye Lingying, Zhang Xinming, Zheng Dawei, et al.
Journal of Materials Processing Technology, 209 (2009), P. 3300 [10] J.
J.of Membrane Science, 172 (2000), p. 199 [3] C.
Nanostructured Materials, 3 (1993), P. 19 [6] C.
Materials Science and Engineering, A220 (1996), P. 69 [8] Ye Lingying, Zhang Xinming, Zheng Dawei, et al.
Journal of Materials Processing Technology, 209 (2009), P. 3300 [10] J.
Online since: May 2020
Authors: A. Ustinov, Eugene Pitukhin
Improving the Efficiency of Protection of the Forest Fire Machine against Forest Fires with the Help of Composite Materials
A.
Traditional materials of which the cabin railings are made are heated quickly and do not effectively resist such extreme conditions.
Development of Fire-Protective Composite Material Good mechanical strength, fire safety, environmental safety open up prospects for the use of composite materials (CM), which actively entered into life and replaced traditional materials in energy, transport, electronics and other fields of activity [6-13].
Volkova, Thermophysical properties of composite materials with polymer matrix and solid solutions, М.: Science education Publ., 2011, 101 p
Shelestov, Thermal Insulation Properties Research of the Composite Material “Water Glass – Graphite Microparticles”, IOP Conference series: Materials science and engineering. 123 (2016) 012018
Traditional materials of which the cabin railings are made are heated quickly and do not effectively resist such extreme conditions.
Development of Fire-Protective Composite Material Good mechanical strength, fire safety, environmental safety open up prospects for the use of composite materials (CM), which actively entered into life and replaced traditional materials in energy, transport, electronics and other fields of activity [6-13].
Volkova, Thermophysical properties of composite materials with polymer matrix and solid solutions, М.: Science education Publ., 2011, 101 p
Shelestov, Thermal Insulation Properties Research of the Composite Material “Water Glass – Graphite Microparticles”, IOP Conference series: Materials science and engineering. 123 (2016) 012018
Online since: October 2025
Authors: Ester Angula, Surendra Kumar Saini, Junestus Negongo, Kalola Ferdinand
Materials Science and Engineering 1305 (2024) 012017
International Journal of Mechanical and Materials Engineering 5 (2010) 182-190
Arabian Journal for Science and Engineering 44 (2019) 5801-5809
Journal of Engineering and Applied Science 70 (2023) 145
Journal of Survey in Fisheries Sciences 10 (2023) 2106-2122
International Journal of Mechanical and Materials Engineering 5 (2010) 182-190
Arabian Journal for Science and Engineering 44 (2019) 5801-5809
Journal of Engineering and Applied Science 70 (2023) 145
Journal of Survey in Fisheries Sciences 10 (2023) 2106-2122
Online since: October 2012
Authors: Ji Ke
Summarize the selection of green building materials, and to judge the development trend of green building materials in China.
first session International Conference materials science 1988 first proposed the concept green building materials.1992 convened by the United Nations Conference Environment and Development.1994 addition of Board "sustainable development", International Organization for Standardization ISO to discuss the development of standards for environmentally friendly products, actively promote development green building materials.
Construction of several green building materials as follows: (1) Cement and concrete: Cement and concrete is the largest amount of building materials, traditional cement use a lot of mineral resources and energy, with the progress of science and technology, has now appeared ecological cement.
References [1] Li'ping Tong: Journal of Zhengzhou university (2008),In Chinese [2] Li'ping Tong: Journal of Zhengzhou university (2008),In Chinese [3] Baizhan Li:The green building introduction.
Chemical industry press(2007),In chinese [4] Shizhong Wang: China building materials science and technology (2003),In Chinese [5] Xinhui Zhang: Energy conservation and environmental protection (2006),In Chinese
first session International Conference materials science 1988 first proposed the concept green building materials.1992 convened by the United Nations Conference Environment and Development.1994 addition of Board "sustainable development", International Organization for Standardization ISO to discuss the development of standards for environmentally friendly products, actively promote development green building materials.
Construction of several green building materials as follows: (1) Cement and concrete: Cement and concrete is the largest amount of building materials, traditional cement use a lot of mineral resources and energy, with the progress of science and technology, has now appeared ecological cement.
References [1] Li'ping Tong: Journal of Zhengzhou university (2008),In Chinese [2] Li'ping Tong: Journal of Zhengzhou university (2008),In Chinese [3] Baizhan Li:The green building introduction.
Chemical industry press(2007),In chinese [4] Shizhong Wang: China building materials science and technology (2003),In Chinese [5] Xinhui Zhang: Energy conservation and environmental protection (2006),In Chinese
Online since: September 2011
Authors: Ming Tian Li, Jun Lian He
Actually, quasi-brittle materials are heterogeneous.
Lattice cellular automata can be used to study the heterogeneity of quasi-brittle materials.
To divide materials into equivalent lattice model. 2.
Quasi-brittle materials such as rock, concrete and so on are usually in compression.
Zhou: International Journal of Rock Mechanics and Mining Sciences, Vol.41(2004), p. 452 [8] B.Q.
Lattice cellular automata can be used to study the heterogeneity of quasi-brittle materials.
To divide materials into equivalent lattice model. 2.
Quasi-brittle materials such as rock, concrete and so on are usually in compression.
Zhou: International Journal of Rock Mechanics and Mining Sciences, Vol.41(2004), p. 452 [8] B.Q.
Online since: October 2013
Authors: Bo Huang
Since friction between the foot and the ground is an important force in most sports, modern athletic shoes are designed to maximize this force, and materials, such as rubber, are used.
Journal of Dance Medicine & Science 2011, Vol. 15 Issue 2, p61 [3] Griffiths, Ian.
Journal of Sports Sciences Feb 2011, Vol. 29 Issue 4, p373 [5] Hagen, Marco; Hennig, Ewald M.
Journal of Sports Sciences Feb 2009, Vol. 27 Issue 3, p267 [6] Hennig, Ewald M.
Journal of Sports Science & Medicine Dec2009, Vol. 8 Issue 4, p607 [8] Odebiyi, Daniel O.; Ajiboye, Eyitola O.; Jaja, Smith I.
Journal of Dance Medicine & Science 2011, Vol. 15 Issue 2, p61 [3] Griffiths, Ian.
Journal of Sports Sciences Feb 2011, Vol. 29 Issue 4, p373 [5] Hagen, Marco; Hennig, Ewald M.
Journal of Sports Sciences Feb 2009, Vol. 27 Issue 3, p267 [6] Hennig, Ewald M.
Journal of Sports Science & Medicine Dec2009, Vol. 8 Issue 4, p607 [8] Odebiyi, Daniel O.; Ajiboye, Eyitola O.; Jaja, Smith I.
Online since: November 2025
Authors: Mykola Riabchykov, Olexandr Alexandrov, Mykyta Alexandrov, Yuriy Sychov
This enables the creation of materials with controlled permeability.
Further research in this field remains highly relevant, particularly in connection with the development of energy-efficient construction and materials science.
Jian, Transient determination of water vapor diffusion coefficient of porous building materials, Journal of Zhejiang University (Engineering Science), 50 1 (2016) 16-20, ISSN 1008-973X, https://doi.org/10.3785/j.issn.1008-973X.2016.01.003
Qu, Experimental determination on the capillary water absorption coefficient of porous building materials: A comparison between the intermittent and continuous absorption tests, Journal of Building Engineering, Volume 28 (2020) 101091, https://doi.org/10.1016/j.jobe.2019.101091
Materials, 17(19) (2024) 4903. https://doi.org/10.3390/ma17194903
Further research in this field remains highly relevant, particularly in connection with the development of energy-efficient construction and materials science.
Jian, Transient determination of water vapor diffusion coefficient of porous building materials, Journal of Zhejiang University (Engineering Science), 50 1 (2016) 16-20, ISSN 1008-973X, https://doi.org/10.3785/j.issn.1008-973X.2016.01.003
Qu, Experimental determination on the capillary water absorption coefficient of porous building materials: A comparison between the intermittent and continuous absorption tests, Journal of Building Engineering, Volume 28 (2020) 101091, https://doi.org/10.1016/j.jobe.2019.101091
Materials, 17(19) (2024) 4903. https://doi.org/10.3390/ma17194903
Online since: September 2013
Authors: Hui Wu, Chang Long Wang, Wen Ni
Methods and Materials
Raw Materials.
International Journal of Minerals, Metallurgy, and Materials. 17 (2010) 116-120
Journal of University of Science and Technology Beijing. 32 (2010) 1253-1257
Journal of University of Science and Technology Beijing.32 (2010) 504-508
International Journal of Minerals, Metallurgy and Materials. 17 (2010) 116-120
International Journal of Minerals, Metallurgy, and Materials. 17 (2010) 116-120
Journal of University of Science and Technology Beijing. 32 (2010) 1253-1257
Journal of University of Science and Technology Beijing.32 (2010) 504-508
International Journal of Minerals, Metallurgy and Materials. 17 (2010) 116-120
Online since: July 2017
Authors: V.I. Yukhvid, Vladimir N. Sanin, M.I. Alymov, Dmitrii Andreev, Vladimir A. Gorshkov
Alymove
Institute of Structural Macrokinetics and Materials Science, Russian Academy of Sciences, Chernogolovka, Moscow, 142432 Russia
a*yukh@ism.ac.ru, bade@ism.ac.ru, csvn@ism.ac.ru, dgorsh@ism.ac.ru, edirector@ism.ac.ru
Keywords: SHS metallurgy, composite material (CM), heat-resistant material (HM), hard alloy (HA).
These composite materials include hard alloys and heat-resistant materials.
Tretyakov, Foundations of materials science and production technology of sintered hard alloys, Moscow, Metallurgiya, 1976
Cao, Combination of mechanochemical activation and self-propagating behaviour for the synthesis of Ti aluminides, Materials Science and Engineering, A361, (2003) 23-28
Journal of Refractory Metals and Hard Materials. 50 (2015) 113-119
These composite materials include hard alloys and heat-resistant materials.
Tretyakov, Foundations of materials science and production technology of sintered hard alloys, Moscow, Metallurgiya, 1976
Cao, Combination of mechanochemical activation and self-propagating behaviour for the synthesis of Ti aluminides, Materials Science and Engineering, A361, (2003) 23-28
Journal of Refractory Metals and Hard Materials. 50 (2015) 113-119
Online since: May 2012
Authors: Song Ren, Song Tao Guo, Tao Deng, Jie Chen, De Yi Jiang
Especially, the creep behavior of similar materials can reflect the Jintan salt rock long-term creep with a relatively short time, which supplies reliable similitude model material for energy storage long-term creep test.
The test selected reference rock depth of 1 000 m of rock salt from Table 1 Physico-mechanical theoretical values of Jintan salt rocks and similar materials Lithology Bulk density (kN/m3) Elastic modulus (GPa) Poisson's ratio Compression strength (MPa) Jintan salt rock[16] 23.0 18 0.30 20 similar materials 23.0 0.36 0.30 0.4 Table 2 The creep-characteristic theoretical values of Jintan salt rocks and similar materials Lithology Load stress /MPa Time /h Initial creep rate /% Steady-state creep rate /% σ3 σ1 Jintan salt rock[8] 0 10 78 0.393 2.0 5 10 76 0.189 0.3 5 15 54 0.198 0.35 similar materials 0 0.2 11 0.393 14.0 0.1 0.2 11 0.189 2.1 0.1 0.3 8 0.198 2.45 Jintan salt mines, Jiangsu province, China.
After extensive groups of similar materials to simulate the salt rock, the similar materials are selected as follows: iron powder: coarse salt particles: fine salt powder: adhesives = 1:0.55:0.2:0.04 The adhesives composite of epoxy resin and ethylenediamine, and the volume ratio is 4:1.
Acknowledgements This research was supported by the Nation Basic Research Program of China(2009CB724606), Chinese Science Foundation (51074198), the Fundamental Research Funds for the Central Universities (CDJXS10240001; CDJXS11241182), Chongqing Natural Science Foundation (No.2010BB6044).
Mechanics of Cohesive-Frictional Materials.1996: 165-197
The test selected reference rock depth of 1 000 m of rock salt from Table 1 Physico-mechanical theoretical values of Jintan salt rocks and similar materials Lithology Bulk density (kN/m3) Elastic modulus (GPa) Poisson's ratio Compression strength (MPa) Jintan salt rock[16] 23.0 18 0.30 20 similar materials 23.0 0.36 0.30 0.4 Table 2 The creep-characteristic theoretical values of Jintan salt rocks and similar materials Lithology Load stress /MPa Time /h Initial creep rate /% Steady-state creep rate /% σ3 σ1 Jintan salt rock[8] 0 10 78 0.393 2.0 5 10 76 0.189 0.3 5 15 54 0.198 0.35 similar materials 0 0.2 11 0.393 14.0 0.1 0.2 11 0.189 2.1 0.1 0.3 8 0.198 2.45 Jintan salt mines, Jiangsu province, China.
After extensive groups of similar materials to simulate the salt rock, the similar materials are selected as follows: iron powder: coarse salt particles: fine salt powder: adhesives = 1:0.55:0.2:0.04 The adhesives composite of epoxy resin and ethylenediamine, and the volume ratio is 4:1.
Acknowledgements This research was supported by the Nation Basic Research Program of China(2009CB724606), Chinese Science Foundation (51074198), the Fundamental Research Funds for the Central Universities (CDJXS10240001; CDJXS11241182), Chongqing Natural Science Foundation (No.2010BB6044).
Mechanics of Cohesive-Frictional Materials.1996: 165-197